Structural Role of (Bacterio)chlorophyll Ligated in the Energetically Unfavorable β-Position

García‐Martín, Adela; Kwa, Lee Gyan; Strohmann, Brigitte; Robert, Bruno; Holzwarth, Alfred R.; Braun, Paula

doi:10.1074/jbc.m510731200

Cited by 21 publications

(20 citation statements)

References 65 publications

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“…Intermolecular hydrogen bond between the peripheral C3 acetyl group and neighboring residues modulates the functional properties, especially the excitation energies of BChl in LH complexes (Fowler et al 1994;Sturgis and Robert 1997). Hydrogen bonding between the C13 1 keto carbonyl group of bacteriochlorophyll-B850 of the b-subunit to the hydroxyl group of serine(-4) of the a-subunit significantly contributes to the assembly and stability of LH2 without apparently affecting its spectral properties (Garcia-Martin et al 2006a;Kwa et al 2004).…”

Section: Introductionmentioning

confidence: 99%

Fine tuning of the spectral properties of LH2 by single amino acid residues

et al. 2008

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The peripheral light-harvesting complex, LH2, of Rhodobacter sphaeroides consists of an assembly of membrane-spanning alpha and beta polypeptides which assemble the photoactive bacteriochlorophyll and carotenoid molecules. In this study we systematically investigated bacteriochlorophyll-protein interactions and their effect on functional bacteriochlorophyll assembly by site-directed mutations of the LH2 alpha-subunit. The amino acid residues, isoleucine at position -1 and serine at position -4 were replaced by 12 and 13 other residues, respectively. All residues replacing isoleucine at position -1 supported the functional assembly of LH2. The replacement of isoleucine by glycine, glutamine or asparagine, however, produced LH2 complex with significantly altered spectral properties in comparison to LH2 WT. As indicated by resonance Raman spectroscopy extensive rearrangement of the bacteriochlorophyll-B850 macrocycle(s) took place in LH2 in which isoleucine -1 was replaced by glycine. The replacement results in disruption of the H-bond between the C3 acetyl groups and the aromatic residues +13/+14 without affecting the H-bond involving the C13(1) keto group. In contrast, nearly all amino acid replacements of serine at position -4 resulted in shifting of the bacteriochlorophyll-B850 red most absorption maximum. Interestingly, the extent of shifting closely correlated with the volume of the residue at position -4. These results illustrate that fine tuning of the spectral properties of the bacteriochlorophyll-B850 molecules depend on their packing with single amino acid residues at distinct positions.

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Section: Introductionmentioning

confidence: 99%

Fine tuning of the spectral properties of LH2 by single amino acid residues

et al. 2008

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“…[1,3,5] Recent findings showed that the 13 1 -carbonyl of β-ligated chlorophylls in LH II has a strong tendency to H-bond with the neighbouring protein subunits, thus manifesting the key role of the ligation face in the antennae structure. [6] 4932 unit forms an ion pair with the chlorin acid group. The binding mechanism was further confirmed by association constants (K a ) obtained from titration experiments in CDCl It is very likely that selective chlorin β-face ligation has been formerly achieved by using a covalent approach by trivially replacing the phytyl group of chlorophyll with an N-propyl imidazole moiety.…”

Section: Introductionmentioning

confidence: 99%

Zn Pyropheophorbide a: A β‐Face Selective Nicotine Receptor

2008

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Nicotine binds to a semisynthetic chlorophyll a derivative, Zn pyropheophorbide a, in a receptor‐like manner to form a 1:1 complex with β‐face diastereomeric configuration. The geometry of the complex structure was evidenced by 1H NMR, ROESY and DOSY spectroscopic experiments combined with molecular modelling DFT B3LYP calculations at the 6‐31G* level. The observed binding between the chlorin and nicotine takes place through a “two‐point binding” mechanism, in which the nicotine N‐pyridyl moiety coordinates to the chlorin zinc atom, whilst the nicotine N‐methyl pyrrolidine unit forms an ion pair with the chlorin acid group. The binding mechanism was further confirmed by association constants (Ka) obtained from titration experiments in CDCl3 with 1H NMR spectroscopic monitoring (8.0 × 105 M–1) and in toluene with UV/Vis (6.1 × 104 M–1) monitoring. The corresponding binding constants obtained for nicotine with one‐point binder, Zn pyropheophorbide a methyl ester, were 4.8 × 105 and 2.3 × 104 M–1, respectively. (© Wiley‐VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2008)

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“…Axial ligation to the central magnesium atom has long been recognized as critical for the binding of (B)Chl and thus for the assembly of (B)Chl proteins 6, 7. There are, however, numerous additional possibilities of interactions with the substituents; in particular, H‐bonding to the carbonyl groups seems to be widespread 8, 9. Additionally, there is the stereochemical aspect in (B)Chl ligation 10–12.…”

Section: Introductionmentioning

confidence: 99%

“…The two faces of the chlorin macrocycle are diastereotopic, and an additional chiral center is therefore generated by ligation of the central magnesium from either the top (α‐type) or the bottom face (β‐type) of the macrocycle [Scheme (C)]; these two ligation states should differ in their binding energies 13, 14. In natural (B)Chl proteins, the two types of ligation are unevenly distributed, and α‐type ligation of (B)Chls is predominant 9, 11. β‐Ligated (B)Chl has been proposed to play an important role in (B)Chl protein assembly 9.…”

Section: Introductionmentioning

confidence: 99%

Design principles for chlorophyll‐binding sites in helical proteins

et al. 2010

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The cyclic tetrapyrroles, viz. chlorophylls (Chl), their bacterial analogs bacteriochlorophylls, and hemes are ubiquitous cofactors of biological catalysis that are involved in a multitude of reactions. One systematic approach for understanding how Nature achieves functional diversity with only this handful of cofactors is by designing de novo simple and robust protein scaffolds with heme and/or (bacterio)chlorophyll [(B)Chls]-binding sites. This strategy is currently mostly implemented for heme-binding proteins. To gain more insight into the factors that determine heme-/(B)Chl-binding selectivity, we explored the geometric parameters of (B)Chl-binding sites in a nonredundant subset of natural (B)Chl protein structures. Comparing our analysis to the study of a nonredundant database of heme-binding helical histidines by Negron et al. (Proteins 2009;74:400-416), we found a preference for the m-rotamer in (B)Chl-binding helical histidines, in contrast to the preferred t-rotamer in heme-binding helical histidines. This may be used for the design of specific heme- or (B)Chl-binding sites in water-soluble helical bundles, because the rotamer type defines the positioning of the bound cofactor with respect to the helix interface and thus the protein-binding site. Consensus sequences for (B)Chl binding were identified by combining a computational and database-derived approach and shown to be significantly different from the consensus sequences recommended by Negron et al. (Proteins 2009;74:400-416) for heme-binding helical proteins. The insights gained in this work on helix- (B)Chls-binding pockets provide useful guidelines for the construction of reasonable (B)Chl-binding protein templates that can be optimized by computational tools.

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Structural Role of (Bacterio)chlorophyll Ligated in the Energetically Unfavorable β-Position

Cited by 21 publications

References 65 publications

Fine tuning of the spectral properties of LH2 by single amino acid residues

Fine tuning of the spectral properties of LH2 by single amino acid residues

Zn Pyropheophorbide a: A β‐Face Selective Nicotine Receptor

Design principles for chlorophyll‐binding sites in helical proteins

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